RU153706U1 - VARIABLE LIGHT DISTRIBUTION LED LAMP - Google Patents

Abstract

1. LED lamp with variable light distribution, containing a cylindrical body, inside which there is an LED light source with pins, and a driver, characterized in that a diffuser is fixed to the outlet of the cylindrical body of heat-conducting material with an annular protrusion, the light source contains a hollow body of heat-conducting material on which there is an LED module with LEDs on one side, pins on the other, and a driver inside it, with an LED light source It olzhen be located so as to provide thermally conductive contact with the cylindrical body to move longitudinally along the optical axis relative to the output otverstiya.2. The LED lamp according to claim 1, characterized in that the inner surface of the cylindrical body has a reflection coefficient of more than 0.8.3. LED lamp 1 and 2, characterized in that the cylindrical body in cross section may take the form of a polyhedron.

Description

The utility model relates to electrical engineering and can be used in the manufacture of LED lamps designed for lighting.

For lighting purposes, halogen incandescent lamps with reflectors such as MR 16 are used to provide accent or general lighting as spotlights [Reference book on lighting engineering / Ed. Yu.B. Eisenberg. - M .: Sign. - 2006. - S. 109.]

A disadvantage of the known lamps is the relatively low light output and short service life.

Halogen lamps are replaced by energy-saving lamps of the MR16 type, in which a compact fluorescent lamp is used as the light source [Energy-saving lamp Elektrostandard MR-16 G5.3 11W [Electronic resource]. - Access mode: http: //www.comfort-16-g53-0].

A disadvantage of the known solution is the presence in them of an environmentally hazardous substance - mercury, which is present both in the process of manufacturing the lamp and in the finished lamp in the process of its operation, where it may be unintentional destruction and, accordingly, environmental pollution. In addition, with the improper disposal of these lamps, the territories of landfills for household waste are contaminated with mercury and its compounds.

A known LED lamp, which is more environmentally friendly due to the exclusion of environmentally hazardous elements and compounds from the lamp design, in addition, the range of this type of lamp is expanded due to the possibility of creating a certain light intensity curve in the process of lamp production. The LED lamp contains a cylindrical housing, inside of which the driver is located. In the lower part of the cylindrical case there is a cover with pins and ventilation holes. In the upper part there are ventilation holes and holes for mounting the LEDs, as well as a reflector attached to the outer surface of the cylindrical body, on which rectangular holes are made with built-in elongated plates of heat-conducting material, having slots at both ends, in one of which LED legs are inserted, and in others, each of which is formed by the curved end of the oblong plate, the outer surface of the cylindrical body rigidly enters [RU, No. 139758, IPC F21S 13/00, publ. 04/20/2014].

A disadvantage of the known solution is the impossibility of changing light distribution during operation, which reduces its performance.

The technical result is to increase the operational qualities of the lamp due to the possibility of changing the light distribution of the LED lamp during operation.

The technical result is achieved by the fact that the LED lamp contains a cylindrical housing, inside of which there is an LED light source with pins, and a driver. A diffuser is fixed to the outlet of the cylindrical body of heat-conducting material with an annular protrusion. The LED light source contains a hollow body of heat-conducting material, on which, on the one hand, there is an LED module with LEDs, on the other, pins, and inside it a driver. The LED light source must be positioned so as to provide heat-conducting contact with the cylindrical body with the possibility of longitudinal movement along the optical axis relative to the outlet. The inner surface of the cylindrical body has a reflection coefficient of more than 0.8. The cylindrical body in cross section may take the form of a polyhedron.

In FIG. 1 shows the construction of a LED lamp with a local section, in FIG. 2 is a light intensity curve with a close proximity of the light source to the outlet of the cylindrical housing of the LED lamp; FIG. 3 - light intensity curve at maximum distance from the outlet of the light source in the cylindrical housing of the LED lamp.

The LED lamp (Fig. 1) contains a cylindrical housing 1 made of heat-conducting material with an annular protrusion 2. A diffuser 3 is fixed to the outlet of the cylindrical housing 1. The inner surface 4 of the cylindrical housing 1 has a reflection coefficient of more than 0.8. Inside the cylindrical housing 1 there is a LED light source 5, which has the possibility of longitudinal movement along the optical axis of the LED lamps by mechanical action on it, and contains a hollow body 6 of heat-conducting material, on which, on the one hand, there is an LED module 7 with LEDs 8, on the other - pins 9, and inside it is driver 10. The LED light source 5 of the heat-conducting material is positioned so as to provide heat-conducting contact with the cylindrical housing 1 of the lamps s. The cylindrical body 1 in cross section may take the form of a polyhedron.

LED lamp operates as follows. By means of an annular protrusion 2, the LED lamp is fixed in a standard lamp for halogen incandescent lamps with reflectors of the MR16 type. When applying a supply voltage to the pins 9 of the light source 5 (Fig. 1), the driver 10 converts it into direct current, which flows through the LEDs 8 of the LED module 7 and causes them to glow. When current flows through the LEDs 8, in the pn junction of the crystal, in addition to the generation of optical radiation, thermal energy is released, which is transmitted to the LED module 7 with LEDs 8. To increase the cooling intensity of the LED module 7, it is attached to the housing of the LED light source 5 with good thermal conductivity, which, in turn, transfers heat to the cylindrical body 1 having a developed external surface and, accordingly, a significantly greater heat transfer to the surrounding space anstvo. To reduce the brightness of the LEDs 8, the outlet of the cylindrical body 1 of the LED lamp is closed by a diffuser 3. The LED light source 5 is able to longitudinally move along the optical axis inside the cylindrical body 1 by mechanical action on it. The type of light intensity curve depends on the location of the LED module 7 of the LED light source 5 relative to the outlet of the cylindrical housing 1 of the LED lamp. So, when the LED module 7 is located on the border of the outlet of the cylindrical body 1 of the LED lamp, the light intensity curve will be determined by the total light intensity curve of the LEDs 8 located on the basis of the LED module 7. In this case, the cosine (Fig. 2). As the LED module 7 with the LEDs 8 is removed from the boundary of the outlet of the cylindrical housing 1 of the LED lamp, its light intensity curve will go to a deep type (Fig. 3). Thus, the LED lamp in the first case is used as a light source for general lighting, and in the second - accent lighting.

Compared with the known solution, the proposed one allows to increase the lamp performance by changing the light distribution of the LED lamp during operation.

Claims (3)

1. LED lamp with variable light distribution, containing a cylindrical body, inside which there is an LED light source with pins, and a driver, characterized in that a diffuser is fixed to the outlet of the cylindrical body of heat-conducting material with an annular protrusion, the light source contains a hollow body of heat-conducting material on which there is an LED module with LEDs on one side, pins on the other, and a driver inside it, with an LED light source It olzhen be located so as to provide thermally conductive contact with the cylindrical body to move longitudinally along the optical axis relative to the outlet. 2. The LED lamp according to claim 1, characterized in that the inner surface of the cylindrical body has a reflection coefficient of more than 0.8. 3. LED lamp according to paragraphs. 1 and 2, characterized in that the cylindrical body in cross section may take the form of a polyhedron.

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